ABCA1 promotes the efflux of bacterial LPS from macrophages and accelerates recovery from LPS-induced tolerance

Macrophages play important roles in both lipid metabolism and innate immunity. We show here that macrophage ATP-binding cassette transporter A1 (ABCA1), a transporter known for its ability to promote apolipoprotein-dependent cholesterol efflux, also participates in the removal of an immunostimulatory bacterial lipid, lipopolysaccharide (LPS). Whereas monocytes require an exogenous lipoprotein acceptor to remove cell-associated LPS, macrophages released LPS in the absence of an exogenous acceptor by a mechanism that was driven, in part, by endogenous apolipoprotein E (apoE). Agents that increased ABCA1 expression increased LPS efflux from wild-type but not ABCA1-deficient macrophages. Preexposure of peritoneal macrophages to LPS for 24 h increased the expression of ABCA1 and increased LPS efflux with a requirement for exogenous apolipoproteins due to suppression of endogenous apoE production. In contrast, LPS preconditioning of ABCA1-deficient macrophages significantly decreased LPS efflux and led to prolonged retention of cell-surface LPS. Although the initial response to LPS was similar in wild-type and ABCA1-deficient macrophages, LPS-induced tolerance was greater and more prolonged in macrophages that lacked ABCA1. Our results define a new role for macrophage ABCA1 in removing cell-associated LPS and restoring normal macrophage responsiveness.     

Effect of vitamin B-12 deprivation on the rates of synthesis and degradation of rat liver fatty acid synthetase

To characterize the basis for the increased hepatic fatty acid synthetase activity in vitamin B-12 deprivation, the content and rates of synthesis and degradation for the enzyme were determined. Animals were in a dietary steady state on normal chow or a B-12-deprived diet; animals on the latter diet were further divided into a “supplemented” group given B-12 and those “B-12-deprived.” The B-12-deprived animals had tissue B-12 depletion. Both total and specific activity of fatty acid synthetase were increased in the B-12-deprived animals, and this was due to increased enzyme protein. Rates of synthesis and degradation were studied in each group after a pulse of 20 μCi of l-[U-¹⁴C]leucine. Radioactivity was determined in the immunoprecipitate of the purified enzyme. Relative rates of synthesis in the B-12-deprived group were increased 8.8-fold over the normal and 3.6-fold over the B-12-supplemented group. Degradation of hepatic fatty acid synthetase was 63 hr ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) in the normal and 65 hr in the B-12-supplemented group. The $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ in the B-12-deprived group was 35 hr. Degradation rates for the soluble protein pool were not affected by B-12 deprivation. The rate constant for synthesis of hepatic fatty acid synthetase in the B-12-deprived group was 14-fold that of the normal and 6-fold that of the B-12-supplemented animals. Thus, although vitamin B-12 deprivation results in increased rate of degradation of fatty acid synthetase, enzyme synthesis is markedly increased yielding a severalfold net increase in synthetase content and activity.